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An Equivariant Lefschetz Fixed-Point Formula for Correspondences

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AN EQUIVARIANT LEFSCHETZ FIXED-POINT FORMULA FOR CORRESPONDENCES IVO DELL’AMBROGIO, HEATH EMERSON, AND RALF MEYER We dedicate this article to Tamaz Kandelaki, who was a coauthor in an earlier version of this article, and passed away in 2012. We will remember him for his warm character and his perseverance in doing mathematics in difficult circumstances. Abstract. We compute the trace of an endomorphism in equivariant bivari- ant K-theory for a compact group G in several ways: geometrically using geometric correspondences, algebraically using localisation, and as a Hattori– Stallings trace. This results in an equivariant version of the classical Lefschetz fixed-point theorem, which applies to arbitrary equivariant correspondences, not just maps. 1. Introduction Here we continue a series of articles by the last two authors about Euler character- istics and Lefschetz invariants in equivariant bivariant K-theory. These invariants were introduced in [11,13–16]. The goal is to compute Lefschetz invariants explicitly in a way that generalises the Lefschetz–Hopf fixed-point formula. Let X be a smooth compact manifold and f : X → X a self-map with simple isolated fixed points. The Lefschetz–Hopf fixed-point formula identifies (1) the sum over the fixed points of f, where each fixed point contributes ±1 depending on its index; (2) the supertrace of the Q-linear, grading-preserving map on K∗(X) ⊗ Q in- duced by f. It makes no difference in (2) whether we use rational cohomology or K-theory because the Chern character is an isomorphism between them. We will generalise this result in two ways. First, we allow a compact group G to act on X and get elements of the representation ring R(G) instead of numbers. Sec- ondly, we replace self-maps by self-correspondences in the sense of [15]. Sections 2 and 3 generalise the invariants (1) and (2) respectively to this setting. The invariant of Section 2 is local and geometric and generalises (1) above; the formulas in Sec- tions 3 and 4 are global and homological and generalise (2) (in two different ways.) arXiv:1303.4777v1 [math.KT] 19 Mar 2013 The equality of the geometric and homological invariants is our generalisation of the Lefschetz fixed-point theorem. A first step is to interpret the invariants (1) or (2) in a category-theoretic way in terms of the trace of an endomorphism of a dualisable object in a symmetric monoidal category. Let C be a symmetric monoidal category with tensor product ⊗ and tensor unit 1. An object A of C is called dualisable if there is an object A∗, called its dual, and a 2010 Mathematics Subject Classification. 19K99, 19K35, 19D55. This research was supported by the Volkswagen Foundation (Georgian–German non- commutative partnership). Heath Emerson was supported by a National Science and Engineering Research Council of Canada Discovery Grant. Ralf Meyer was supported by the German Research Foundation (Deutsche Forschungsgemeinschaft (DFG)) through the Institutional Strategy of the University of Göttingen. 1 2 IVO DELL’AMBROGIO, HEATH EMERSON, AND RALF MEYER natural isomorphism C(A ⊗ B, C) =∼ C(B, A∗ ⊗ C) for all objects B and C of C. Such duality isomorphisms exist if and only if there are two morphisms η : 1 → A⊗A∗ and ε: A∗ ⊗A → 1, called unit and counit of the duality, that satisfy two appropriate conditions. Let f : A → A be an endomorphism in C. Then the trace of f is the composite endomorphism η braid id ∗ ⊗f ε 1 −→ A ⊗ A∗ −−−→ A∗ ⊗ A −−−−−→A A∗ ⊗ A −→ 1, where braid denotes the braiding isomorphism. In this article we also call the trace the Lefschetz index of the morphism. This is justified by the following example. Let C be the Kasparov category KK with its usual tensor product structure, A = C(X) for a smooth compact manifold X, and fˆ ∈ KK0(A, A) for some mor- phism. We may construct a dual A∗ from the tangent bundle or the stable normal bundle of X. In the case of a smooth self-map of X, and assuming a certain transver- sality condition, the trace of the morphism fˆ induced by the self-map equals the invariant (1), that is, equals the number of fixed-points of the map, counted with ap- propriate signs. This is checked by direct computation in Kasparov theory, see [13] for more general results. This paper springs in part from the reference [13]. A similar invariant to the Lefschetz index was introduced there, called the Lefschetz class (of the morphism). The Lefschetz class for an equivariant Kasparov endomorphism of X was defined as an equivariant K-homology class for X. The Lefschetz index, that is, the categorical trace, discussed above, is the Atiyah–Singer index of the Lefschetz class of [13]. The main goal of this article is to give a global, homological formula for the Lefschetz index generalising the invariant (2) for a non-equivariant self-map. The formulation and proof of our homological formula works best for Hodgkin Lie groups. A more complicated form applies to all compact groups. The article [13] also provides two formulas for the equivariant Lefschetz class whose equality generalises that of the invariants (1) and (2), but the methods there are completely different. The other main contribution of this article is to compute the geometric expres- G sion for the Lefschetz index in the category kk of geometric correspondences introduced in [15]. This simplifies the computationc in Kasparov’s analytic theory in [13] and also gives a more general result, since we can work with general smooth correspondences rather than just maps. Furthermore, using an idea of Baum and Block in [4], we give a recipe for composing two smooth equivariant correspondences under a weakening of the usual transversality assumption (of [6]). This technique is important for computing the Lefschetz index in the case of continuous group ac- tions, where transversality is sometimes difficult to achieve, and in particular, aids in describing equivariant Euler characteristics in our framework. Section 2 contains our geometric formula for the Lefschetz index of an equivari- ant self-correspondence. Why is there a nice geometric formula for the Lefschetz index of a self-map in Kasparov theory? A good explanation is that Connes and Skandalis [6] describe KK-theory for commutative C∗-algebras geometrically, in- cluding the Kasparov product; furthermore, the unit and counit of the KK-duality for smooth manifolds have a simple form in this geometric variant of KK. An equivariant version of the theory in [6] is developed in [15]. In Section 2, we also recall some basic results about the geometric KK-theory introduced in [15]. If X is G a smooth compact G-manifold for a compact group G, then KK∗ (C(X), C(X)) is G isomorphic to the geometrically defined group kk∗ (X,X). Its elements are smooth correspondences c b f (1.1) X ←− (M, ξ) −→ X EQUIVARIANT LEFSCHETZ FIXED-POINT FORMULA 3 ∗ consisting of a smooth G-map b,aKG-oriented smooth G-map f, and ξ ∈ KG(M). Theorem 2.18 computes the categorical trace, or Lefschetz index, of such a corre- spondence under suitable assumptions on b and f. Assume first that X has no boundary and that b and f are transverse; equiva- lently, for all m ∈ M with f(m)= b(m) the linear map Db−Df : TmM → Tf(m)X is surjective. Then (1.2) Q := {m ∈ M | b(m)= f(m)} is naturally a KG-oriented smooth manifold. We show that the Lefschetz index is ∗ the G-index of the Dirac operator on Q twisted by ξ|Q ∈ KG(Q) (Theorem 2.18). More generally, suppose that the coincidence space Q as defined above is merely assumed to be a smooth submanifold of M, and that x ∈ TX and Df(ξ)= Db(ξ) implies that ξ ∈ TQ. Then we say that f and b intersect smoothly. For example, the identity correspondence, where f and b are the identity maps on X, does not satisfy the above transversality hypothesis, but f and b clearly intersect smoothly. In the case of a smooth intersection, the cokernels of the map Df − Db form a vector bundle on Q which we call the excess intersection bundle η. This bundle measures the failure of transversality of f and b. Let η be KG-oriented. Then TQ also inherits a canonical KG-orientation. The restriction of the Thom class of η to ∗ the zero section gives a class e(η) ∈ KG(Q). Then Theorem 2.18 asserts that the Lefschetz index of the correspondence (1.1) with smoothly intersecting f and b is the index of the Dirac operator on the coin- cidence manifold Q twisted by ξ ⊗ e(η). This is the main result of Section 2. In Section 3 we generalise the global homological formula involved in the classical Lefschetz fixed-point theorem, to the equivalent situation. This involves completely different ideas. The basic idea to use Künneth and Universal Coefficient theorems for such a formula already appears in [9]. In the equivariant case, these theorems become much more complicated, however. The new idea that we need here is to first localise KKG and compute the Lefschetz index in the localisation. In the introduction, we only state our result in the simpler case of a Hodgkin Lie group G. Then R(G) is an integral domain and thus embeds into its field ∗ G of fractions F . For any G-C -algebra A, K∗ (A) is a Z/2-graded R(G)-module. G G Thus K∗ (A; F ) :=K∗ (A) ⊗R(G) F becomes a Z/2-graded F -vector space.
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